S Peuchen

Nitric oxide-mediated inhibition of the mitochondrial respiratory chain in cultured astrocytes.

Abstract: The Ca2+‐independent form of nitric oxide synthase was induced in rat neonatal astrocytes in primary culture by incubation with lipopolysaccharide (1 µg/ml) plus interferon‐γ (100 U/ml), and the activities of the mitochondrial respiratory chain components were assessed. Incubation for 18 h produced 25% inhibition of cytochrome c oxidase activity. NADH‐ubiquinone‐1 reductase (complex I) and succinate‐cytochrome c reductase (complex II–III) activities were not affected. Prolonged incubation for 36 h gave rise to a 56% reduction of cytochrome c oxidase activity and a 35% reduction in succinate‐cytochrome c reductase activity, but NADH‐ubiquinone‐1 reductase activity was unchanged. Citrate synthase activity was not affected by any of these conditions. The inhibition of the activities of these mitochondrial respiratory chain complexes was prevented by incubation in the presence of the specific nitric oxide synthase inhibitor NG‐monomethyl‐l‐arginine. The lipopolysaccharide/interferon‐γ treatment of the astrocytes produced an increase in glycolysis and lactate formation. These results suggest that inhibition of the mitochondrial respiratory chain after induction of astrocytic nitric oxide synthase may represent a mechanism for nitric oxide‐mediated neurotoxicity.

Energy Thresholds in Brain Mitochondria POTENTIAL INVOLVEMENT IN NEURODEGENERATION

Decreases in mitochondrial respiratory chain complex activities have been implicated in neurodegenerative disorders such as Parkinson’s disease, Huntington’s disease, and Alzheimer’s disease. However, the extent to which these decreases cause a disturbance in oxidative phosphorylation and energy homeostasis in the brain is not known. We therefore examined the relative contribution of individual mitochondrial respiratory chain complexes to the control of NAD-linked substrate oxidative phosphorylation in synaptic mitochondria. Titration of complex I, III, and IV activities with specific inhibitors generated threshold curves that showed the extent to which a complex activity could be inhibited before causing impairment of mitochondrial energy metabolism. Complex I, III, and IV activities were decreased by approximately 25, 80, and 70%, respectively, before major changes in rates of oxygen consumption and ATP synthesis were observed. These results suggest that, in mitochondria of synaptic origin, complex I activity has a major control of oxidative phosphorylation, such that when a threshold of 25% inhibition is exceeded, energy metabolism is severely impaired, resulting in a reduced synthesis of ATP. Additionally, depletion of glutathione, which has been reported to be a primary event in idiopathic Parkinson’s disease, eliminated the complex I threshold in PC12 cells, suggesting that antioxidant status is important in maintaining energy thresholds in mitochondria. The implications of these findings are discussed with respect to neurodegenerative disorders and energy metabolism in the synapse.

Nitric oxide-mediated mitochondrial damage: A potential neuroprotective role for glutathione

In this study we have investigated the mechanisms leading to mitochondrial damage in cultured neurons following sustained exposure to nitric oxide. Thus, the effects upon neuronal mitochondrial respiratory chain complex activity and reduced glutathione concentration following exposure to either the nitric oxide donor, S-nitroso-N-acetylpenicillamine, or to nitric oxide releasing astrocytes were assessed. Incubation with S-nitroso-N-acetylpenicillamine (1 mM) for 24 h decreased neuronal glutathione concentration by 57%, and this effect was accompanied by a marked decrease of complex I (43%), complex II-III (63%), and complex IV (41%) activities. Incubation of neurons with the glutathione synthesis inhibitor, L-buthionine-[S,R]-sulfoximine caused a major depletion of neuronal glutathione (93%), an effect that was accompanied by a marked loss of complex II-III (60%) and complex IV (41%) activities, although complex I activity was only mildly decreased (34%). In an attempt to approach a more physiological situation, we studied the effects upon glutathione status and mitochondrial respiratory chain activity of neurons incubated in coculture with nitric oxide releasing astrocytes. Astrocytes were activated by incubation with lipopolysaccharide/interferon-gamma for 18 h, thereby inducing nitric oxide synthase and, hence, a continuous release of nitric oxide. Coincubation for 24 h of activated astrocytes with neurons caused a limited loss of complex IV activity and had no effect on the activities of complexes I or II-III. However, neurons exposed to astrocytes had a 1.7-fold fold increase in glutathione concentration compared to neurons cultured alone. Under these coculture conditions, the neuronal ATP concentration was modestly reduced (14%). This loss of ATP was prevented by the nitric oxide synthase inhibitor, NG-monomethyl-L-arginine. These results suggest that the neuronal mitochondrial respiratory chain is damaged by sustained exposure to nitric oxide and that reduced glutathione may be an important defence against such damage.

Distribution of mRNAs Encoding the Peroxisome Proliferator-Activated Receptor α, β, and γ and the Retinoid X Receptor α, β, and γ in Rat Central Nervous System

Abstract: We report the isolation, by RT‐PCR, of partial cDNAs encoding the rat peroxisome proliferator‐activated receptor (PPAR) isoforms PPARα, PPARβ, and PPARγ and the rat retinoid X receptor (RXR) isoforms RXRα, RXRβ, and RXRγ. These cDNAs were used to generate antisense RNA probes to permit analysis, by the highly sensitive and discriminatory RNase protection assay, of the corresponding mRNAs in rat brain regions during development. PPARα, PPARβ, RXRα, and RXRβ mRNAs are ubiquitously present in different brain regions during development, PPARγ mRNA is essentially undetectable, and RXRγ mRNA is principally localised to cortex. We demonstrate, for the first time, the presence of PPAR and RXR mRNAs in primary cultures of neonatal meningeal fibroblasts, cerebellar granule neurons (CGNs), and cortical and cerebellar astrocytes and in primary cultures of adult cortical astrocytes. PPARα, PPARβ, RXRα, and RXRβ mRNAs are present in all cell types, albeit that PPARα and RXRα mRNAs are at levels near the limit of detection in CGNs. PPARγ mRNA is expressed at low levels in most cell types but is present at levels similar to those of PPARα mRNA in adult astrocytes. RXRγ mRNA is present either at low levels, or below the level of detection of the assay, for all cell types studied.

Interrelationships between astrocyte function, oxidative stress and antioxidant status within the central nervous system

Astrocytes have, until recently, been thought of as the passive supporting elements of the central nervous system. However, recent developments suggest that these cells actually play a crucial and vital role in the overall physiology of the brain. Astrocytes selectively express a host of cell membrane and nuclear receptors that are responsive to various neuroactive compounds. In addition, the cell membrane has a number of important transporters for these compounds. Direct evidence for the selective co-expression of neurotransmitters, transporters on both neurons and astrocytes, provides additional evidence for metabolic compartmentation within the central nervous system. Oxidative stress as defined by the excessive production of free radicals can alter dramatically the function of the cell. The free radical nitric oxide has attracted a considerable amount of attention recently, due to its role as a physiological second messenger but also because of its neurotoxic potential when produced in excess. We provide, therefore, an in-depth discussion on how this free radical and its metabolites affect the intra and intercellular physiology of the astrocyte(s) and surrounding neurons. Finally, we look at the ways in which astrocytes can counteract the production of free radicals in general by using their antioxidant pathways. The glutathione antioxidant system will be the focus of attention, since astrocytes have an enormous capacity for, and efficiency built into this particular system.

Mechanisms of intracellular calcium regulation in adult astrocytes

Microfluorimetric techniques were used to measure changes in intracellular calcium in astrocytes cultured from the forebrain of the adult rat. Application of ATP consistently raised intracellular calcium. The response persisted in the absence of extracellular calcium, but then quickly declined upon repeated agonist application. Thapsigargin abolished responses to nucleotides following depletion of the endoplasmic reticular calcium stores. Calcium release was inhibited by caffeine, but was dramatically increased through inositol phosphate receptor sensitization by the sulphydryl reagent thimerosal. Responses to repeated nucleotide applications resulted in a gradual decline of peak calcium concentrations, suggesting a (post)receptor-mediated desensitization or gradual depletion of the internal calcium stores. Subsequent application of ionomycin suggested intracellular calcium depletion as the relevant mechanism. Depletion of the internal calcium stores with ATP, ionomycin or thapsigargin failed to reveal a calcium influx pathway. These results suggest that the capacitative mechanism of calcium entry does not operate in response to nucleotide receptor activation in these cells, and that the immediate refilling of the internal calcium stores is primarily determined by re-uptake of cytosolic calcium into the endoplasmic reticulum. A complete refilling of this calcium store by extracellular calcium may be a much slower process. Control of these signal transduction pathways is crucial to the maintenance of the calcium/energy homeostasis of the adult astrocyte in the central nervous system.

Energy metabolism of adult astrocytes in vitro

In this study we established cultures of astrocytes from the forebrain of the adult rat. The homeostatic regulatory mechanisms of the aerobic and anaerobic pathways of energy metabolism in these cells showed that adult astrocytes express many of the regulatory properties previously demonstrated in neonatal astrocytes. Changes in mitochondrial respiration and ATP production were readily evident upon incubation with the relevant substrates. Inhibition of mitochondrial respiration led to a compensatory increase in anaerobic glycolysis as evidenced by an increased release of lactate. We assessed the role of cytosolic calcium in the regulation of the mitochondrial energy metabolism. Increases in cytosolic calcium concentration in response to ATP or stimulation of mechanical receptors were followed by depolarizations of the mitochondrial membrane potential, whose magnitude reflected the amplitude of the cytosolic calcium response. The changes in mitochondrial membrane potential were largely dependent on the presence of external calcium. These results provide the first evidence of a signalling mechanism in astrocytes by which changes in cytosolic calcium mediate changes in respiration, possibly through mitochondrial calcium uptake and subsequent activation of several mitochondrial dehydrogenases. This signalling pathway would thus ensure that energy demands due to changes in cytosolic calcium concentrations are met by increases in energy production through increases in mitochondrial oxidative phosphorylation.

Evaluation of the efficacy of potential therapeutic agents at protecting against nitric oxide synthase-mediated mitochondrial damage in activated astrocytes

Within the central nervous system, nitric oxide is an important physiological messenger. However, when synthesized excessively in neurones, cell death may occur. An impairment of mitochondrial cytochrome oxidase and subsequent cellular energy depletion seems to be a likely mechanism for this neurotoxicity. Within neurones, nitric oxide is synthesized by the constitutive, Ca(2+)-dependent form of nitric oxide synthase (nNOS). Astrocytes, however, possess both the constitutive and the inducible Ca(2+)-independent NOS (iNOS), which is expressed by endotoxin and/or cytokines. In vitro, activation of nNOS rapidly produces neuronal cell death. In contrast to neurones, following induction of iNOS, astrocytes synthesize large quantities of nitric oxide, but cell death is not apparent despite marked damage to mitochondrial cytochrome oxidase. The resistance of astrocytes to nitric oxide synthase-mediated cell damage may be due to their ability to increase their glycolytic rate when mitochondrial ATP synthesis is compromised. On the basis of this phenomenon, we propose that activated astrocytes represent a suitable system for studying the efficacy of potential therapeutic agents at protecting from nitric oxide synthase-mediated mitochondrial damage.

REGULATION OF THE KETOGENIC ENZYME MITOCHONDRIAL 3-HYDROXY-3- METHYLGLUTARYL-COA SYNTHASE IN ASTROCYTES AND MENINGEAL FIBROBLASTS Implications in Normal Brain Development and Seizure Neuropathologies

Metabolic fuels may be defined as complex carbon molecules that can be exploited for the energy released upon breakage of their carbon-carbon bonds. Fatty acids and hexoses, principally glucose, represent the two major classes of such complex carbon molecules that are used for fuel by eukaryotes. Typically, glucose is first metabolized anaerobically (glycolysis) to three-carbon molecules (pyruvate, phosphoenolpyruvate) which then provide the precursors of the tricarboxylic acid or Krebs cycle, ie: oxaloacetate and acetyl-CoA. The cycling of such intermediates via the Krebs cycle then effects the con-

Identification of a 58-kDa antigen with increased immunoreactivity in the cerebella of multiple sclerosis patients

An increase in immunoreactivity associated with a 58-kDa antigen was found in a majority of MS cerebellar homogenates examined by Western blot analysis using antisera obtained by selective immunization of rabbits with autopsy cerebella. Two-dimensional immunoblotting demonstrated that the majority of the increased immunoreactivity observed in MS cerebella was associated with the highest apparent pI of three immunoreactive species at 58 kDa. Immuno-crossreaction with rat cerebellar homogenates demonstrated that the 58-kDa antigen was developmentally regulated, showing the greatest immunoreactivity at embryonic day 15. The 58-kDa cerebellar antigen may represent a membrane protein which is re-expressed as part of the onset of MS.